Genetics of resistance to the African trypanosomes. III. Variant-specific antibody responses of H-2-compatible resistant and susceptible mice

Genetically based differences in variant-specific immunity to the African trypanosomes were examined. H-2-compatible inbred mouse strains that differed in relative resistance were infected with Trypanosoma rhodesiense clone LouTat 1. Antibody responses to exposed epitopes of the LouTat 1 variant-specific surface glycoprotein (VSG) were measured. Relatively resistant B10.BR mice (H-2k) made predictable IgM antibody responses to the VSG of LouTat 1 which were associated with clearance of the LouTat 1 variant antigenic type from blood; IgG responses to LouTat 1 surface antigen appeared after clearance occurred, and were lower than peak titers of IgM. Intermediately susceptible CBA mice (H-2k) also made predictable IgM and IgG responses which followed the same pattern as the more resistant strain. Peak titers were lower for both Ig classes, however, and a delayed appearance of antibody was correlated with delayed clearance of LouTat 1. In contrast to B10.BR and CBA mice, the susceptible C3H mice (H-2k) failed to make detectable antibodies to LouTat 1 surface antigen and also failed to control the first peak of parasitemia. The absence of immunity in infected C3H mice was selective for antibody to exposed epitopes of LouTat 1 VSG because antibody was detectable to invariant VSG or internal trypanosome antigens. Also, the C3H strain was shown not to be a genetic nonresponder to LouTat 1 surface antigen because VSG-specific antibodies appeared within 1 wk after trypanocidal chemotherapy. Finally, we demonstrated that the susceptibility of C3H mice was not associated with an inability of the mononuclear phagocyte system to clear the parasites because drug cure, passive transfer of immune serum, or sensitization of trypanosomes with antibody all led to trypanosome clearance from blood by the liver. In summary, we show for the first time that major differences in variant-specific immunity occur in MHC-compatible animals after infection with the African trypanosomes.     

Attachment of Trypanosoma brucei to rabbit peritoneal exudate cells

Attachment of trypanosomes to cultured rabbit peritoneal cells was enhanced in the presence of hyperimmune Trypanosoma brucei antiserum and sera from infected rabbits. During infection attachment rose rapidly from control levels reaching a maximum value after two or three weeks; this was maintained until the death of the animal. The initial rise in activity was preceded by an increase in the serum titres of trypanosome agglutinating antibody. Attachment did not appear to be mediated by variant specific antibodies, no association being found between adherence and the appearance of successive variant subpopulations. Fractionation of hyperimmune and immune sera indicated that the majority of activity was present in the gamma globulin fraction with less activity in the macroglobulin fraction, despite its elevation during infection. Increased activity obtained with partially-purified immunoglobulin G prepared from hyperimmune serum was reduced following absorption with either disrupted or live trypanosomes.     

Trypanosoma lewisi: effects of immunosuppression on the serological reactivities of exoantigens and cellular antigens of bloodstream parasites.

Groups of rats were immunosuppressed with antithymocyte serum (ATS) and infected with Trypanosoma lewisi. Immunodiffusion studies were performed which demonstrated that trypanosome exoantigens, present in the plasma of these animals, were precipitated by antibodies in the sera of rats undergoing a typical primary T. lewisi infection; extracts of trypanosomes which had been collected from ATS-treated rats contained antigens which also were precipitated by antibodies in these sera. These precipitating antibodies could not be detected using either the plasma of untreated infected rats or extracts of trypanosomes which had been collected from untreated rats. With the exoantigens, precipitating antibodies were detected in serum samples collected from rats 14 to 250 days after infection. With the extract, precipitating antibodies were found as early as 5 days after infection and could be detected as late as 90 days after infection. Antigens of trypanosome extracts partially blocked the precipitin reactions between antisera and exoantigens, suggesting the presence of common antigens in the two preparations. Intact trypanosomes were serologically more reactive when collected from immunosuppressed rats. Trypanosomes collected from ATS-treated rats were agglutinated by antisera at titers fourfold higher than trypanosomes collected from untreated hosts. Absorption with exoantigens from immunosuppressed infected rats blocked trypanosome agglutination, indicating that these antigens are of cell surface origin. The experiments suggest that a likely result of immunosuppressing the host is a trypanosome antigen preparation that is a more reactive serodiagnostic reagent.     

The dynamics of antigenic variation and growth of African trypanosomes

Antigenic variation in African trypanosomes, which is a simple strategy for survival in the immune host, is rendered complex by its magnitude. For protection from nonspecific immunity and escape from specific immunity, each trypanosome is covered by a replaceable surface coat composed of the variant surface glycoprotein (VSG), which specifies the variable antigen type (VAT) of the trypanosome. Antigenic variation is the process by which the trypanosome switches from one coat to another. Here, David Barry and Michael Turner consider this phenomenon within the context of the course of trypanosome infection.     

Lymphocyte function in experimental African trypanosomiasis. V. Role of antibody and the mononuclear phagocyte system in variant-specific immunity

The role of parasite-specific antibody and the mononuclear phagocyte system (MPS) in immunity to the African trypanosomes was examined. For this study C57BL/10SnJ mice were infected with Trypanosoma rhodesiense clone LouTat 1.0. Infected mice were injected with 75Se-labeled LouTat 1.0 trypanosomes, and clearance from the blood upon reexposure was measured throughout the course of infection. Clearance of labeled organisms occurred only on or after day 5, which was the day of natural elimination of LouTat 1.0 from the blood. Clearance was dependent on a functional immune system and correlated with the appearance of antibody to the variant-specific surface antigen (VSSA) of the trypanosomes. The ability to clear trypanosomes was transferred to normal, uninfected mice by immune serum. Both the IgM and IgG fractions of immune serum mediated the clearance, and VSSA-specific IgM fractions were as efficient in clearing LouTat 1.0 as the IgG fractions. Normal levels of complement (C3) were not required for clearance. The liver was the primary organ of clearance, and the ability of the liver to sequester radiolabeled trypanosomes was not impaired in the terminal phase of the disease or by large numbers of circulating trypanosomes present representing different variant antigenic types (VAT). We conclude that in African trypanosomiasis the MPS is not depressed in its ability to clear trypanosomes of the infecting VAT at any time during the course of infection. The observed clearance function requires parasite-specific antibody but normal levels of C3.     

Anti-Trypanosoma brucei activity in Cape buffalo serum during the cryptic phase of parasitemia is mediated by antibodies

Cape buffalo are reservoir hosts of African trypanosomes. They rapidly suppress population growth of the highly antigenically variable extracellular haemoprotozoa and subsequently maintain a cryptic infection. Here we use in vitro cultures of trypanosomes cloned from Cape buffalo blood during cryptic infection, as well as related and unrelated trypanosomes, to identify anti-trypanosome components present in cryptic-phase infection serum. Trypanosome clone-specific complement-dependent trypanolytic IgM and IgG arose after appearance of target trypanosomes during cryptic infection. Serum collected late in the cryptic phase of infection contained complement-independent growth-inhibitory IgG which varied in activity among target trypanosomes. Removal of protein A/G-binding IgG from the serum restored its capacity to support trypanosome growth in vitro. Recovered growth-inhibitory IgG reacted with the variable surface glycoprotein (VSG) of parasites most affected by it, and reacted with trypanosome common antigens, notably the endosome-restricted tomato lectin-binding glycoproteins (TL-antigens). The inclusion of purified TL-antigens in culture medium did not affect the trypanosome growth-inhibitory activity of immune Cape buffalo serum. In addition, hyperimmune rabbit IgG against TL-antigens showed little or no binding to intact trypanosomes and did not affect trypanosome growth in vitro although it did react strongly with TL-antigens and trypanosome endosomes. We conclude that antibodies, particularly clone-specific (putatively VSG-specific) antibodies are responsible for the anti-trypanosome activity of cryptic phase infection serum consistent with a dominant role in parasite control in Cape buffalo.     

Modulation of innate immunity by African trypanosomes

The experimental studies of Brucei group trypanosomes presented here demonstrate that the balance of host and parasite factors, especially IFN-γ GPI-sVSG respectively, and the timing of cellular exposure to them, dictate the predominant MP and DC activation profiles present at any given time during infection and within specific tissues. The timing of changes in innate immune cell functions following infection consistently support the conclusion that the key events controlling host resistance occur within a short time following initial exposure to the parasite GPI substituents. Once the changes in MP and DC activities are initiated, there appears little that the host can do to reverse these changes and alter the final outcome of these regulatory events. Instead, despite the availability of multiple innate and adaptive immune mechanisms that can control parasites, there is an inability to control trypanosome numbers sufficiently to prevent the emergence and establishment of virulent trypanosomes that eventually kill the host. Overall it appears that trypanosomes have carefully orchestrated the host innate and adaptive immune response so that parasite survival and transmission, and alterations of host immunity, are to its ultimate benefit.     

Trypanosoma brucei: anti-tubulin antibodies specifically inhibit trypanosome growth in culture

We previously observed that trypanosome tubulin immunizes mice against infection by this parasite. Here we describe the direct effect of anti-tubulin antibodies on trypanosomes, using rabbit antibodies to renatured (nTbTub) or SDS-PAGE denatured (dTbTub) Trypanosoma brucei tubulin. We also evaluate antibodies to synthetic tubulin peptides (STP) and rat brain tubulin (RbTub). The anti-nTbTub serum strongly inhibited trypanosome proliferation in culture, and immunoagglutinated trypanosomes even after heat inactivation of complement. The anti-dTbTub and the anti-STP sera also inhibited trypanosome growth and immunoagglutinated trypanosomes, but to a lesser extent than the anti-nTbTub, whereas the anti-RbTub serum had no effect. In Western blots these antibodies were species specific. Immunofluorescence showed that the surface of intact trypanosomes was not uniformly stained by any of these antibodies, but cells that had been permeabilised were labeled throughout the cytoplasm. This suggests that the variant surface glycoproteins (VSG) played no part in the generation of these inhibitory antibodies.     

Genetics of resistance to the African trypanosomes. VII. Trypanosome virulence is not linked to variable surface glycoprotein expression

The question of linkage of virulence traits to variable surface glycoprotein (VSG) expression in African trypanosomiasis was addressed. Previously we demonstrated that daughter cells arising in mice infected with a genetically homogeneous trypanosome population of Trypanosoma brucei rhodesiense were more virulent than the infecting population (J. A. Inverso and J. M. Mansfield, J. Immunol. 130:412, 1983). These virulent trypanosomes expressed differences in surface phenotype compared with the infecting variant types, and we proposed that virulence may be "linked" to VSG expression. In the present study, however, we have shown that expression of virulence is independent of the VSG phenotype displayed by trypanosome populations. A VSG-identical but highly virulent subpopulation of T. b. rhodesiense LouTat 1 was derived by rapid subpassage and subcloning in immunosuppressed mice. The virulent LouTat 1A subclone derived in this manner killed B10.BR/SgSnJ mice in 3 to 4 days postinfection compared with approximately 60 days for the parent clone, LouTat 1. The virulent subclone LouTat 1A appears to express the same VSG as the less virulent LouTat 1 population, as determined by polyspecific and monoclonal antibody-binding assays, cross-protection tests, and amino acid sequence analyses of the N-terminal portion of the VSG molecules. When LouTat 1 and subclone LouTat 1A were injected into a heterologous host species, multiple variant antigenic types (VATs) arising from each inoculum were isolated and characterized. VATs derived from the virulent subclone were as uniformly virulent for B10.BR mice as LouTat 1A. In summary, these results demonstrate that trypanosome virulence, once expressed, is a stable phenotype that does not seem to be associated with a particular VSG phenotype, nor does virulence change with the expression of different VSG genes.     

T. brucei infection reduces B lymphopoiesis in bone marrow and truncates compensatory splenic lymphopoiesis through transitional B-cell apoptosis

African trypanosomes of the Trypanosoma brucei species are extracellular protozoan parasites that cause the deadly disease African trypanosomiasis in humans and contribute to the animal counterpart, Nagana. Trypanosome clearance from the bloodstream is mediated by antibodies specific for their Variant Surface Glycoprotein (VSG) coat antigens. However, T. brucei infection induces polyclonal B cell activation, B cell clonal exhaustion, sustained depletion of mature splenic Marginal Zone B (MZB) and Follicular B (FoB) cells, and destruction of the B-cell memory compartment. To determine how trypanosome infection compromises the humoral immune defense system we used a C57BL/6 T. brucei AnTat 1.1 mouse model and multicolor flow cytometry to document B cell development and maturation during infection. Our results show a more than 95% reduction in B cell precursor numbers from the CLP, pre-pro-B, pro-B, pre-B and immature B cell stages in the bone marrow. In the spleen, T. brucei induces extramedullary B lymphopoiesis as evidenced by significant increases in HSC-LMPP, CLP, pre-pro-B, pro-B and pre-B cell populations. However, final B cell maturation is abrogated by infection-induced apoptosis of transitional B cells of both the T1 and T2 populations which is not uniquely dependent on TNF-, Fas-, or prostaglandin-dependent death pathways. Results obtained from ex vivo co-cultures of living bloodstream form trypanosomes and splenocytes demonstrate that trypanosome surface coat-dependent contact with T1/2 B cells triggers their deletion. We conclude that infection-induced and possibly parasite-contact dependent deletion of transitional B cells prevents replenishment of mature B cell compartments during infection thus contributing to a loss of the host's capacity to sustain antibody responses against recurring parasitemic waves.     

Evidence for reappearance of Trypanosoma brucei variable antigen types in relapse populations.

Seven out of 11 bovines infected with different clones of Trypanosoma brucei showed 2 peaks of antibody activity against the infecting clone within 7 weeks, as measured by immunofluorescence, radioimmunoassay, and neutralization of infectivity tests. Using other clones from an unrelated Stock, antibodies to these clones were not detectable, indicating that the antibodies produced were specific to the infecting organisms. These results suggest that there was a reappearance or increase in numbers of the infecting organisms or of organisms with variable surface antigens similar to those of the infecting clones. The reappearance of variable antigen types in the presence of specific antibodies would imply that antibody plays a selective rather than an inductive role in the process of antigenic variation in African trypanosomes.     

Genetics of resistance to the African trypanosomes. IV. Resistance of radiation chimeras to Trypanosoma rhodesiense infection

The cellular bases of resistance to the African trypanosomes were examined in inbred mice. As part of these studies, reciprocal bone marrow cell transplants were performed between H-2 compatible mice which differ in relative resistance to Trypanosoma brucei rhodesiense infection. Survival times, parasitemias and IgM antibody responses to the surface antigen of the infecting variant type were measured in these semiallogeneic bone marrow chimeras. Relatively resistant C57BL/10 mice, intermediate A.By mice, and least resistant C3H.SW mice that were reconstituted after lethal irradiation with syngeneic bone marrow cells displayed resistance and immunity characteristic of the homologous donor strain. When C57BL/10 mice were reconstituted with C3H.SW mouse bone marrow cells they retained the ability to produce antibodies to trypanosome surface antigen but the antibody titers were significantly reduced. Control of parasitemia and mean survival time were reduced in these chimeras, but differed significantly from C3H.SW mice. A.By mice that received cells from C57BL/10 donors exhibited antibody responses and survival times similar to the C57BL/10 mice. Survival times of A.By mice given syngeneic cells or C3H.SW cells were the same, but the antibody responses of A.By mice given C3H.SW cells were lower than those of A.By mice given syngeneic cells. C3H.SW mice reconstituted with C57BL/10 bone marrow cells were capable of making antibodies and controlling parasitemia, in marked contrast to the absence of such responses in C3H.SW mice reconstituted with syngeneic cells. Survival times, however, were indistinguishable from those of C3H.SW mice given syngeneic cells. Thus, resistance to T. b. rhodesiense was shown for the first time to depend on donor bone marrow derived cells as well as upon radiation-resistant cells/factors associated with host genetic background. Also, parasite-specific IgM antibody responses seem to be regulated by a mechanism which does not depend on bone marrow derived cells alone, and the presence of such immune responses is not linked to survival time.     

The GPI-Phospholipase C of Trypanosoma brucei Is Nonessential But Influences Parasitemia in Mice

In the mammalian host, the cell surface of Trypanosoma brucei is protected by a variant surface glycoprotein that is anchored in the plasma membrane through covalent attachment of the COOH terminus to a glycosylphosphatidylinositol. The trypanosome also contains a phospholipase C (GPI-PLC) that cleaves this anchor and could thus potentially enable the trypanosome to shed the surface coat of VSG. Indeed, release of the surface VSG can be observed within a few minutes on lysis of trypanosomes in vitro. To investigate whether the ability to cleave the membrane anchor of the VSG is an essential function of the enzyme in vivo, a GPI-PLC null mutant trypanosome has been generated by targeted gene deletion. The mutant trypanosomes are fully viable; they can go through an entire life cycle and maintain a persistent infection in mice. Thus the GPI-PLC is not an essential activity and is not necessary for antigenic variation. However, mice infected with the mutant trypanosomes have a reduced parasitemia and survive longer than those infected with control trypanosomes. This phenotype is partially alleviated when the null mutant is modified to express low levels of GPI-PLC.     

IFN-gamma-dependent nitric oxide production is not linked to resistance in experimental African trypanosomiasis

Resistance to African trypanosomes is dependent on B cell and Th1 cell responses to the variant surface glycoprotein (VSG). While B cell responses to VSG control levels of parasitemia, the cytokine responses of Th1 cells to VSG appear to be linked to the control of parasites in extravascular tissues. We have recently shown that IFN-gamma knockout (IFN-gamma KO) mice are highly susceptible to infection and have reduced levels of macrophage activation compared to the wild-type C57BL/6 (WT) parent strain, even though parasitemias were controlled by VSG-specific antibody responses in both strains. In the present work, we examine the role of IFN-gamma in the induction of nitric oxide (NO) production and host resistance and in the development of suppressor macrophage activity in mice infected with Trypanosoma brucei rhodesiense. In contrast to WT mice, susceptible IFN-gamma KO mice did not produce NO during infection and did not develop suppressor macrophage activity, suggesting that NO might be linked to resistance but that suppressor cell activity was not associated with resistance or susceptibility to trypanosome infection. To further examine the consequence of inducible NO production in infection, we monitored survival, parasitemia, and Th cell cytokine production in iNOS KO mice. While survival times and parasitemia of iNOS KO mice did not differ significantly from WT mice, VSG-specific Th1 cells from iNOS KO mice produced higher levels of IFN-gamma and IL-2 than cells from WT mice. Together, these results show for the first time that inducible NO production is not the central defect associated with susceptibility of IFN-gamma KO mice to African trypanosomes, that IFNgamma-induced factors other than iNOS may be important for resistance to the trypanosomes, and that suppressor macrophage activity is not linked to either the resistance or the susceptibility phenotypes.     

Trypanosoma rhodesiense: variant specificity of immunity induced by irradiated parasites.

Rats immunized with irradiated Trypanosoma rhodesiense resisted infection with the homologous strain. When similarly immunized rats were challenged with parasites obtained from rhesus monkeys infected with the same strain, resistance depended on when parasites were obtained from the donor monkeys. Immunized rats challenged with trypanosomes obtained from a monkey during the first peak of parasitemia were solidly immune; immunized rats challenged with trypanosomes obtained from monkeys after their initial peak of parasitemia all succumbed to the challenging infection. These observations indicate that parasites of a variant antigenic specificity arose during the course of the monkey infections. Neutralization tests performed on the various isolates from rats and monkeys using antiserum obtained from immunized rats confirmed that the immunity produced by irradiated trypanosomes was variant specific.     

Exposed epitopes on a Trypanosoma equiperdum variant surface glycoprotein altered by point mutations.

African trypanosomes are covered by a dense protein layer that is immunologically distinct on different trypanosome isolates and is termed the variant surface glycoprotein (VSG). The different VSGs are expressed in a general order, where some VSGs appear preferentially early in infection and others only later. The exposed epitopes on a late antigen, VSG 78, of T.equiperdum were studied by the technique of monoclonal antibody (MAb) escape selection. MAbs that neutralize trypanosomes bearing VSG 78 reacted with the VSG only when it was attached to the trypanosome surface, suggesting that the most immunogenic surface epitopes are conformational. Trypanosome clones resistant to one of the MAbs yet still expressing VSG 78 or 78(20) were isolated in vitro. Two independent variants resistant to MAb H3 changed Ser192 to Arg by a single base change in the VSG gene and a variant resistant to MAb H21 had a single base change that converted Gln172 to Glu. A variant resistant to MAb H7 had several changes in the VSG gene, a gene conversion in the 5' region and an isolated mutation in codon 220 that is proposed to be responsible for the resistance phenotype. The isotypic bias of the MAbs against VSG 78 and an analysis of the natural variants that are resistant to MAb 78H21 suggest that glycosylation plays a role in the immunogenicity of these proteins. The analysis defines some of the exposed amino acid residues and demonstrates that VSG genes are altered by mutations and small gene conversions as well as replaced by large gene conversion-like events. The results provide biological data supporting the model of VSG structure obtained by crystallographic studies.     

Regulation of B cell responses to the variant surface glycoprotein (VSG) molecule in trypanosomiasis. I. Epitope specificity and idiotypic profile of monoclonal antibodies to the VSG of Trypanosoma brucei rhodesiense.

Regulatory mechanisms governing B cell responses to the trypanosome variant surface glycoprotein (VSG) molecule currently are being studied. As a fundamental basis for examining such regulation, the epitope specificities and idiotypic profiles of murine mAb produced to the VSG of Trypanosoma brucei rhodesiense clone LouTat 1.5 were determined. Variant specific mAb were used to probe VSG proteolytic peptides in Western blot analysis, to serve as competitive inhibitors in RIA analyses with purified VSG molecules, and to examine membrane-binding patterns of labeled trypanosome cells in order to evaluate epitope specificities. By using these approaches, a conformational epitope expressed only on the VSG 1.5 surface coat of viable trypanosomes was detected, and two nonconformationally determined epitope clusters were recognized within the subsurface V region of the VSG 1.5 molecule. The subsurface epitope clusters may be repeated on the VSG molecule because each was present on more than one proteolytic VSG peptide fragment. Idiotypic profiles of selected VSG-specific mAb subsequently were determined with xenogeneic antiidiotypic typing sera. Results from competitive inhibition RIA analyses using these reagents demonstrated that varying levels of idiotypic cross-reactivity exist among the subsurface VSG epitope-specific mAb; this cross-reactivity extended to idiotope(s) expressed by a mAb recognizing a surface conformational epitope of the VSG 1.5 molecule. Analysis of complementary idiotypic/antiidiotypic antibody pairs revealed that these specific interactions were inhibited by purified VSG 1.5 but not by purified VSG 1.9, which was derived from a heterologous variant antigenic type. The model mAb described here, and reagents recognizing their idiotypic markers, comprise a foundation for analysis of idiotypic regulation of VSG-specific B cell responses during infection.     

Trypanosoma rhodesiense blood forms express all antigen specificities relevant to protection against metacyclic (insect form) challenge

Monoclonal antibodies were used to demonstrate the expression of four distinct metacyclic (infective insect form) trypanosome antigens on blood forms of T. rhodesiense. Metacyclic antigens were consistently expressed on the blood forms on days 4 and 5 of the first parasitemia after metacyclic infection of C57BL/6 mice. In different mice examined, the percent of blood forms expressing metacyclic antigens ranged from 46 to 85%. Immunization with irradiated day-5 blood form trypanosomes was protective against metacyclic challenge, indicating that all antigen specificities relevant to protective immunization against metacyclic challenge are expressed on blood form trypanosomes. Blood forms, in contrast to metacyclic forms, can be isolated in quantities sufficient for purification of antigens and genetic cloning.